JP3021843U - Frozen control ducts for freezers and refrigerators - Google Patents

Abstract

(57) Abstract: The present invention is by contacting a member having a function of temporarily changing the shape of the binding of H _{2 O} of H _{2 O} contained in the air, H ₂ It is intended to provide a frosted control duct for a freezer and a refrigerator that temporarily changes the method of coupling O _{2 to} generate frost generated by the coupling of H ₂ O and dew physical properties. A ceramic plate (28A) is provided on the base end (14) side in a large-thickness portion (18) of a duct body (12).
Are provided, and three ceramic plates (28B) are provided vertically next to the ceramic plate (28A). Small thickness part (22) of the duct body (12)
There are two ceramic plates (28C), one ceramic plate (28D), and one ceramic plate (28E) from the base end portion (14) side toward the tip end portion (20).
, Two ceramic plates (28F), and two ceramic plates (28G).

Description

[Detailed description of the device]

[0001]

[Technical field to which the device belongs]

INDUSTRIAL APPLICABILITY The present invention provides a frosted control duct for a freezer or a refrigerator that has a function of acting on H ₂ O contained in the air in the freezer or the refrigerator and temporarily changing the shape of the H ₂ O bond. Regarding

[0002]

[Prior art]

 Conventionally, frost adheres to walls, ceilings, and stored products in freezers and refrigerators. For this reason, the frost attached to the product or the like melts due to the temperature change in the freezer or the refrigerator, which affects the taste of the product or the package gets wet and changes. In addition, if frost attached to the walls or ceiling falls on the floor and freezes, there are problems such as impediment to walking and forklift operation. Furthermore, frost adheres to the refrigerant in the air circulation passage for lowering the temperature of the freezer or the refrigerator, which significantly reduces the cooling effect, resulting in an increase in power consumption.

[0003]

[Problems to be solved by the device]

The present invention was devised to eliminate the above-mentioned inconvenience, and H ₂ O contained in the air is brought into contact with a member having a function of temporarily changing the shape of the H ₂ O bond. by, there is provided a freezer, a refrigerator frost with control duct to inhibit physical properties become frost or dew temporarily changing the manner of binding of H ₂ O produced by the binding of H ₂ O to each other .

[0004]

[Means for Solving the Problems]

The invention according to claim 1 is a duct arranged in a freezer or a refrigerator, and has a function of acting on H ₂ O contained in the air and temporarily changing the binding form of H ₂ O. Frozen control ducts for freezers and refrigerators, which are characterized by having built-in components. The invention according to claim 2 is a duct disposed in a freezer or a refrigerator, the duct main body being formed in a tubular body, an air intake port formed at one end of the duct main body, and the duct main body. A ceramic that has an air outlet formed at the other end of the duct and a function that acts on H ₂ O contained in the air that is arranged inside the duct body and that temporarily changes the shape of the H ₂ O bond. And a plate. According to a third aspect of the present invention, there is provided a duct arranged in a freezer or a refrigerator, the duct main body having a tubular shape, an air intake port formed at one end of the duct main body, and the duct main body. A ceramic that has an air outlet formed at the other end of the duct and a function that acts on H ₂ O contained in the air that is arranged inside the duct body and that temporarily changes the shape of the H ₂ O bond. It is characterized in that it has a plate and a fan arranged inside the duct main body near the air intake port.

[0005]

[Embodiment of device]

1 to 4 show a first embodiment of a frosted control duct for a freezer and a refrigerator according to the present invention. As shown in FIG. 1 and FIG. 2, the duct body (12) of the duct (10) is formed in a rectangular tube shape from an appropriate material such as aluminum, stainless steel, and plywood veneer. A large-thickness portion (18) extends from the proximal end portion (14) to the intermediate portion (16) of the duct body (12), and a small thickness portion extends from the distal end portion (20) of the duct body (12) to the intermediate portion (16). Thick portions (22) are formed respectively. A cold air suction port (24) is formed on the end face of the base end portion (14) of the duct body (12), and a cool air discharge port (26) is formed on the end face of the tip end portion (20) of the duct body (12). Has been formed. In addition, as shown in FIG. 1, a member having a function of temporarily changing the shape of the H ₂ O bond in the large thickness portion (18) of the duct body (12) on the proximal end portion (14) side. As the ceramic plates (28A), four ceramic plates (28A) are arranged at intervals in the vertical direction (vertical direction in FIG. 1) in a shelf shape. Next to these ceramic plates (28A), three ceramic plates (28B) are arranged in the vertical direction (vertical direction in FIG. 1) with a shelf-like interval. The ceramic plate (28A) and the ceramic plate (28B) are arranged in different steps. Inside the small thickness portion (22) of the duct body (12), ceramic plates (28C) are vertically shaped (vertical direction in FIG. 1) from the base end portion (14) side toward the tip end portion (20) in a shelf shape. The two ceramic plates (28D) are arranged next to each other, and the ceramic plates (28E) are arranged next to each other in the vertical direction (up and down direction in FIG. 1) in a shelf shape. And two ceramic plates (28F) are arranged next to each other, and ceramic plates (28G) are arranged next to each other in the vertical direction (vertical direction in FIG. 1) in a shelf shape. Two are installed. The ceramic plate (28C), the ceramic plate (28D), the ceramic plate (28E), the ceramic plate (28F) and the ceramic plate (28G) are arranged so as to be staggered from each other. As shown in FIG. 3, the ceramic plate (28A) is formed by sintering ceramic powder into a plate shape, the upper surface of which is formed into a saw blade shape, and the lower surface thereof is formed into a flat shape. Further, through holes (30) are formed at the four corners of the ceramic plate (28A). A support pipe (not shown) is fitted in the through hole (30) so that ceramic plates (28A) arranged vertically as shown in FIG. 1 can be arranged in parallel at intervals. Further, as shown in FIG. 3, in this embodiment, the ceramic plate (28A) has a length L of 270 mm, a width W of 190 mm, a thickness T5 of 5 mm, and a thickness T2 of 10 mm. It is said that. The ceramic plates (28B), (28C), (28D), (28E), (28F) and (28G) are made of the same material and the same shape as the ceramic plate (28A).

Next, the operation of the duct (10) of the first embodiment will be described. First, as shown in FIG. 4, when the duct (10) is installed in the freezer (1), the cool air outlet (2A) of the cooling device (2) installed inside the freezer (1) and the duct body. The duct (10) is arranged so as to face the cold air intake port (24) of (12). Therefore, when the cooling device (2) is started, the cold air blown out from the cold air outlet (2A) of the cooling device (2) flows from the cold air intake port (24) of the duct main body (12) to the duct main body as indicated by an arrow A. (12) Enter inside. Moreover, since the cool air blown out from the cool air outlet (2A) of the cooling device (2) is put into the inside of the duct body (12), the H ₂ O suspended in the freezer (1) is efficiently supplied by the flow of the cool air. It can be sent inside the duct body (12). The cool air that has entered the inside of the duct body (12) passes between the ceramic plate (28A) and the ceramic plate (28A), and between the ceramic plate (28A) and the duct body (12), and the ceramic plate (28B). ) And the ceramic plate (28B) and between the ceramic plate (28B) and the duct body (12) to flow from the large thickness portion (18) to the small thickness portion (22). The cold air that has entered the small thickness portion (22) passes between the ceramic plate (28C) and the ceramic plate (28C) and between the ceramic plate (28C) and the duct body (12), and the ceramic plate (28D). ) And the duct body (12), between the ceramic plate (28E) and the ceramic plate (28E), between the ceramic plate (28E) and the duct body (12), and the ceramic plate (28F). Between the ceramic plate (28G) and the ceramic plate (28G), between the ceramic plate (28G) and the duct body (12), and the cool air exhaust port ( 26) flows out of the duct body (12). Therefore, the cold air entering from the cold air intake port (24) is discharged from the cold air exhaust port (26) until the ceramic plates (28A), (28B), (28C), (28D), (28E), (28F). , (28G), and H ₂ O reacts with the contact for 1/3000 seconds. Therefore, the ceramic temporarily changes the binding method of H ₂ O contained in the cold air into OH, OH, and HH, thereby hindering the physical properties of frost and dew. It should be noted that the control duct (10) of the present invention not only reduces the generation of frost and dew, but also saves energy by significantly reducing the operating time of the compressor.

[0007]

Second Embodiment FIGS. 5 and 6 show a second embodiment of a frosted control duct for a freezer and a refrigerator according to the present invention. The same components as those in the first embodiment are designated by the same reference numerals and the description thereof will be omitted. A plate (42) is provided on the end surface of the base end portion (14) of the duct body (12) of the duct (40). A circular cold air inlet (44) is formed in the center of the plate (42). A fan (46) is arranged in the duct body (12) near the cold air intake port (44). Therefore, by rotating the fan (46), cool air can efficiently enter the duct body (12) through the cool air suction port (44). An air discharge opening (48) is also formed on the side surface of the duct body (12) of the cool air discharge port (26) of the duct body (12). The rest of the configuration and operation are the same as in the first embodiment, so a description thereof will be omitted.

In the embodiment, as shown in FIG. 1, the ceramic plates (28A), (28B), (28C), (28D), (28E), (28F) and (28G) are horizontally connected to the duct body ( 12), but even if the ceramic plates (28A), (28B), (28C), (28D), (28E), (28F), (28G) are tilted and provided on the duct body (12). Good. In the embodiment, as shown in FIG. 1, four ceramic plates (28A), three ceramic plates (28B), two ceramic plates (28C), one ceramic plate (28D), and one ceramic plate (28D). Two plates (28E), one ceramic plate (28F) and two ceramic plates (28G) were installed, but the ceramic plates (28A), (28B), (28C), (28D), ( Of course, the numbers of 28E), (28F), and (28G) are not limited to this. In the embodiment, the ducts (10) and (40) are provided in the freezer (1), but the ducts (10) and (40) may be provided in the refrigerator. Further, in the embodiment, the upper surfaces of the ceramic plates (28A), (28B), (28C), (28D), (28E), (28F), (28G) are formed in a sawtooth shape, but the sawtooth shape is not always necessary. Need not be formed.

[0009]

[Effect of device]

As described above, the frosted control duct of the freezer and the refrigerator according to the present invention is a member such as a ceramic plate that temporarily changes the shape of the H ₂ O bond and is included in the cold air. _By bringing ₂ O into contact and physically changing the binding state of H ₂ O, frost and dew are less likely to be generated, and the excellent quality of the product can be maintained. In addition, it has an excellent effect of preventing frost from being frozen on the floor surface and maintaining a cooling effect of a freezer or a refrigerator to prevent an increase in power consumption.

[Brief description of drawings]

FIG. 1 is a sectional view of a frosted control duct of a freezer and a refrigerator according to a first embodiment.

FIG. 2 is a perspective view of a frosted control duct of the freezer and the refrigerator according to the first embodiment.

FIG. 3 is a perspective view of a ceramic plate.

FIG. 4 is a schematic mounting cross-sectional view of a frosted control duct of the freezer and the refrigerator of the first embodiment.

FIG. 5 is a sectional view of a frosted control duct of a freezer and a refrigerator according to a second embodiment.

FIG. 6 is a perspective view of a frosted control duct of a freezer and a refrigerator according to a second embodiment.

[Explanation of symbols]

 (10) ... Frozen control duct for freezer and refrigerator (12) ... Duct body (24) ... Cold air inlet (26) ... Cold air outlet (28A) ... Ceramic plate (28B) · · Ceramic plate (28C) · · Ceramic plate (28D) · · Ceramic plate (28E) · · Ceramic plate (28F) · · Ceramic plate (28G) · · Ceramic plate (40) · Freezer, refrigerator frost Control duct (46) with fan

Claims (3)

[Scope of utility model registration request] 1. A duct arranged in a freezer or a refrigerator, which acts on H ₂ O contained in the air to temporarily generate H 2.
A frosted control duct for a freezer or a refrigerator, which has a built-in member having a function of changing the shape of the ₂ O bond. 2. A duct arranged in a freezer or a refrigerator, the duct body having a tubular shape, an air intake port formed at one end of the duct body, and the other end of the duct body. An air discharge port formed in the section, a ceramic plate disposed inside the duct body and having a function of acting on H ₂ O contained in the air and temporarily changing the shape of the bond of H ₂ O, A frosted control duct for a freezer or a refrigerator. 3. A duct arranged in a freezer or a refrigerator, the duct body having a tubular shape, an air intake port formed at one end of the duct body, and the other end of the duct body. An air discharge port formed in the section, a ceramic plate disposed inside the duct body and having a function of acting on H ₂ O contained in the air and temporarily changing the shape of the bond of H ₂ O, A fan disposed inside the duct main body near the air intake port,
Control duct with frost in the refrigerator.